DE2916221B1 - Skull trepan - Google Patents

Description

The invention relates to a cranial trephine with a drive shaft that can be connected to a drive one overhanging the drive shaft and rotatably mounted on it, one at its free end ring-shaped auxiliary milling cutter-carrying, sleeve-shaped housing, with one in the extension of the drive shaft axially displaceable main milling cutter protruding over the auxiliary milling cutter inside the housing, by means of a protruding over its circumference, in a recess on the inside of the Housing engaging coupling element is rotatably connectable to the housing, with one of the Main cutter in the axial direction away from the drive shaft pressing spring, with coupling elements on the Front side of the main milling cutter for the non-rotatable coupling of the main milling cutter and the drive shaft through positive locking when the main cutter is pressed axially against the drive shaft, with at least one in the wall of the Drive shaft displaceably mounted in the radial direction locking body by an inside the hollow drive shaft axially displaceable, with at least one recess in its circumference provided locking bolt in a first position, in

ORIGINAL INSPECTED

which he extends over the circumference of the drive shaft protrudes, engages in a recess on the inside of the sleeve-shaped housing and thereby securing the housing against axial displacement on the drive shaft, and in a second position is displaceable, in which the recess in its circumference receives the locking body in such a way that this no longer protrudes over the circumference of the drive shaft and thus an axial displaceability of the Housing on the drive shaft allows, and with a shifting the locking bolt into the first position Feather.

Skull stairs of this type have proven to be excellent as so-called automatic skull stairs suitable, as the milling cutters automatically detach from the drive shaft after the skull drilling has been completed and thus a risk of injury to the brain mass below the pierced cranial bone is excluded will. Skull stairs of this type are assembled from a number of individual parts, and it it is necessary to completely dismantle it into these individual parts for cleaning purposes.

For this purpose, the lock described at the beginning has proven to be well suited, in which the housing carrying the auxiliary cutter and mounted on the drive shaft is held in the axial direction by a lock on the drive shaft, which engages in a recess on the inside of the housing in the outer wall of the drive shaft in the radial direction displaceable jo locking body. For the radial displacement of the locking body of the drive shaft is hollow interior provided a slidable in the axial direction locking bolt in a known Schädeltrepan which is held by a compression spring in a position i ~> in which rest against the locking body on its periphery, and thereby the over the circumference Drive shaft protrude and engage in the recess on the inside of the housing. The locking bolt can be displaced against the action of the spring in the axial direction so that the locking bodies in the wall of the drive shaft can enter a recess in the circumference of the locking bolt, the locking bodies releasing the housing and allowing it to move axially on the drive shaft.

In known cranial climbing frames of this type, the displacement of the locking bolt inside the hollow drive shaft achieved by means of a pin through a concentric bore of the drive shaft the locking bolt was moved through it against the action of the spring. This construction has has not proven to be beneficial in practice, as a separate tool is required for this. There is the risk that, especially when assembling the cranial staircase, the sterile parts of the staircase through this tool will be contaminated. In addition, the right tool must be used at the right time Hand, and this too can lead to difficulties in practice.

It is the object of the invention to improve a cranial trepan of the type described above in such a way that that the locking and unlocking of the individual parts without the use of a separate tool is possible. This task is performed with a skull strike> 5 pan of the type described above solved according to the invention in that for axial displacement of the locking bolt on this one in the drive shaft displaceably mounted in the axial direction rests and that axially immovable on the drive shaft, rotatable about the longitudinal axis of the drive shaft Cam track is mounted, wherein the driver rests on the cam track and when rotated the same in is displaceable in the axial direction.

With this construction it is done in the simplest way by turning the cam track relative to the Drive shaft possible to retract the locking body into the drive shaft or to extend it out of it, without the need for a separate tool.

It is advantageous if the driver is a pin which diametrically penetrates the drive shaft and which is in two axially parallel elongated holes is guided in the wall of the drive shaft.

In the preferred embodiment of the invention it is provided that the cam track in the axial direction under the pressure of the locking bolt displacing spring rests against a stop attached to the drive shaft, which is preferably a Can be ring flange.

It is also advantageous if both the drive shaft and the cam track have a handle flange are provided so that the relative rotation of the cam track with respect to the drive shaft is facilitated will.

Further advantageous refinements of the invention are the subject of the subclaims.

The following description of preferred embodiments of the invention serves in context with the drawing for a more detailed explanation. It shows

F i g. 1 is a longitudinal sectional view of a cranial staircase according to the invention;

F i g. 2 shows a partial side view of the cranial staircase according to the invention in the area of the cam track and FIG
F i g. 3 is a sectional view taken along line 3-3 in FIG. 1.
The cranial treadmill shown in the drawing has a hollow drive shaft 1 which has a connecting bolt 3 provided with flattened side surfaces 2, with the aid of which it can be connected to a known type of drive, not shown in the drawing, in a rotating test. A sleeve-shaped housing 4 is pushed onto the free end of the drive shaft 1, the inner surface of which rests tightly against the peripheral surface of the drive shaft 1 and projects beyond the free end 5 of the drive shaft 1. An annular auxiliary milling cutter 6 is either integrally formed or rigidly connected at the free end of the sleeve-shaped housing 4.

In the extension of the drive shaft 1, a main milling cutter 7 is located in the interior of the sleeve-shaped housing 4 stored, which is guided with his body inside the annular auxiliary milling cutter 6 and with his Cutting 8 protrudes over the cutting edge of the auxiliary milling cutter 6. The main milling cutter 7 is in the housing 4 in axially displaceable and is diametrically penetrated by a driving pin 9, which in corresponding Grooves 10 engage in the inner wall of the housing 4 so that the main milling cutter 7 on the one hand and the housing 4 on the other hand, are connected to the auxiliary milling cutter 6 in a rotationally fixed manner.

Inside the hollow drive shaft 1 is a spring bolt 11, which is inside a hollow Lock bolt 12 is mounted displaceably in the axial direction. The spring bolt 11 protrudes with an extension 13 out through the end face 5 of the drive shaft 1 and lies with its spherical end 14 in a

pan-shaped recess 15 in the end face 16 of the Main milling cutter 7. At the opposite end 17 of the spring bolt 11, a compression spring 18 is supported the other end on the inside of the end face 19 of the following locking bolt, which will be described in more detail 12 is present. As a result, the main milling cutter 7 is pushed away from the drive shaft 1 via the spring bolt 11.

The end face 5 of the drive shaft 1 and the end face 16 of the main milling cutter 7 are annular Coupling elements 20 and 21 with sawtooth-shaped engagement elements 22 and 23, respectively. When the main router 7 is shifted against the action of the compression spring 18 in the axial direction, the coupling elements arrive 20 and 21 engage and connect the main milling cutter (and the one with this via the pin 9 and the Grooves 10 connected auxiliary milling cutter) rotatably with the drive shaft. As soon as the axial displacement of the Main milling cutter 7 stops, for example because the skull bone is pierced and there is no axial resistance is more available, the main milling cutter moves away from the drive shaft, so that the rotary joint is resolved immediately.

The locking bolt 12, which is mounted in the interior of the drive shaft 1 so as to be displaceable in the axial direction, has the shape a sleeve closed on one side into which a circumferential groove 24 is pierced. The locking bolt is pressed under the action of the compression spring 18 against a driver 25, which is in axially parallel slots 26,27 of the drive shaft is displaceably guided. The driver 25 protrudes on both sides over the Scope of the drive shaft 1 out. It is secured against displacement in its longitudinal direction by that a screw 28 is screwed radially into it, the head 29 of which in a central opening 30 in the The end face 19 of the locking bolt 12 engages.

As can best be seen from Fig.2, is on the Drive shaft 1 is mounted on a cam track 31 so as to be rotatable about the longitudinal axis of drive shaft 1. The cam track 31 is connected to a handle flange 32 and rests against an annular flange-shaped stop 33 of the Drive shaft 1 on. The free ends of the pin-shaped driver 25 are under the action of Compression spring 18 pressed against cam track 31.

The cam track 31 has different areas 34, 35 and 36 (FIG. 2) where the driver 25 is at Rotation of the cam disc comes to rest in succession. The compression spring is in contact with the area 34 relaxed to the maximum, tensioned to the maximum when the system is in area 36. The inclined area 35 connects areas 34 and 36.

In the preferred embodiment, there are two opposing areas 34 and two opposing Areas 36 are provided which are each offset from one another by 90 °. The areas 36 have an indentation 37 into which the driver 25 can engage under the action of the compression spring 18.

As shown in FIG. 1 can be seen, are in radial recesses 38 of the wall 39 of the drive shaft 1 in present case designed as balls locking body 40 arranged in the radial direction displaceable, but secured against falling out of the drive shaft 1 in the radial direction. When these locking bodies rest on the outer circumference of the locking bolt 12, as shown in FIG. 1 shown is, they protrude over the circumference of the drive shaft 1 and engage in a recess 41 on the Inside of the housing 4, so that this is secured against axial displacement.

If the locking bolt is moved against the action of the compression spring 18, the circumferential groove is reached 24 in the area of the recesses 38, so that the spherical locking body 40 radially can move inside, releasing the housing 4 in the axial direction. In this position the Skull trephine can be disassembled into its individual parts.

The displacement of the locking bolt in the axial direction takes place with the construction described in simply by rotating the cam track relative to the drive shaft, for what purpose the Drive shaft has a handle flange 42 protruding in the radial direction. If the driver is in Area 34 is applied, the housing is locked (normal position) when the driver in area 36 and in particular in the indentation 37 is applied, is the

Locking of the housing 4 released (open position).

In this way, the lock can be released in an uncomplicated manner without using a tool will.

The shape of the cam track can be different. In Fig. 2 is an embodiment in solid lines shown, in which the area 34 and the area 36 parallel to the axis of the drive shaft Connect running areas 43, which together with the driver 25 as rotary stops for the cam track to serve. However, it is also possible to use the cam track in the dash-dotted line in FIG Form lines shown way, so that the rotation from the normal position to the open position and vice versa take place in both directions can.

1 sheet of drawings

Claims (12)

Patent claims: 1. Skull trepan with a drive shaft that can be connected to a drive, with one the drive shaft overlapping and rotatably mounted on this, an annular at its free end Sleeve-shaped housing carrying auxiliary milling cutters, with an in the extension of the drive shaft in the Inside the housing axially displaceably mounted, above the auxiliary cutter protruding main cutter, the by means of a protruding over its circumference, in a recess on the inside of the housing engaging coupling element is rotatably connectable to the housing, with one of the Main cutter in the axial direction pushing away from the drive shaft spring, with coupling elements on the end faces of the drive shaft and on the opposite end face of the main milling cutter non-rotatable coupling of the main milling cutter and the drive shaft through positive locking in the axial Pressing the main cutter onto the drive shaft, with at least one in the wall of the drive shaft in the radial direction displaceably mounted locking body, which by an inside the hollow drive shaft axially displaceable, with at least one recess in its circumference provided locking bolt in a first position in which it extends over the circumference of the drive shaft protrudes, engaging in a recess on the inside of the sleeve-shaped housing and thereby secures the housing against axial displacement on the drive shaft and in a second Position is displaceable in which the recess in its circumference the locking body receives in such a way that it no longer protrudes beyond the circumference of the drive shaft and thus allows an axial displaceability of the housing on the drive shaft, and with one of the Lock bolt in the first position shifting spring, characterized in that for axial displacement of the locking bolt (21) on this one in the drive shaft (1) in the axial direction Direction of slidably mounted driver (25) and that on the drive shaft (1) axially immovably, a cam track (31) is mounted so that it can rotate about the longitudinal axis of the drive shaft (1), wherein the driver (25) rests against the cam track (31) and in the axial direction when it is rotated Direction is shiftable. 2. cranial trephine according to claim 1, characterized in that the driver (25) is a die Drive shaft (1) is diametrically penetrating pin, which is in two axially parallel elongated holes (26, 27) is guided in the wall (39) of the drive shaft (1). 3. cranial trephine according to one of claims 1 or 2, characterized in that the cam track (31) in the axial direction under the pressure of the spring (18) displacing the locking bolt (12) a stop (33) attached to the drive shaft (1) rests. 4. cranial trephine according to claim 3, characterized in that the stop is an annular flange (33) is. 5. cranial trephine according to one of claims 3 or 4, characterized in that the cam track (31) has a first area (34) on which the driver (25) rests when the Housing (4) on the drive shaft (1) is secured against axial displacement, with the locking bolt (12) moving spring (18) is in its most relaxed position. 6. cranial trephine according to one of claims 3 to 5, characterized in that the cam track (31) in a second area (36), on which the driver (25) when the spring (18) is maximally tensioned rests, has an indentation (37) in which ίο the driver (25) when the housing (4) is unlocked engages under the action of the spring (18) displacing the locking bolt (12). 7. cranial trephine according to claim 6, characterized in that two diametrically opposed first and two diametrically opposite second regions (34 and 36, respectively) are provided. 8. cranial trephine according to one of claims 6 or 7, characterized in that the first and second areas (34 and 36) with the cam track (31) are connected on both sides via an inclined area (35). 9. cranial trephine according to one of claims 6 or 7, characterized in that the first and second areas (34 and 36) each one parallel to the axis of the drive shaft (1) Area (43) adjoins, which serves as a rotation stop for the cam track (31). 10. cranial trephine according to one of claims 2 to 9, characterized in that the pin-shaped driver (25) to secure against a shift in its longitudinal direction one laterally in a recess (30) of the locking bolt (12) has engaging projection (29). 11. cranial trephine according to claim 10, characterized -S5, that the projection is a radial Direction in the driver (25) screwed screw (28). 12. cranial trephine according to one of the preceding claims, characterized in that both the The drive shaft (1) and the cam track (31) are provided with a handle flange (42 or 32).